Admittance and Impedance Representations of Friction Based on Implicit Euler Integration

Author

Kikuuwe, Ryo ; Takesue, Naoyuki ; Sano, Akihito ; Mochiyama, Hiromi ; Fujimoto, Hideo

Author_Institution

Dept. of Mech. Eng., Nagoya Inst. of Technol.

Volume

22

Issue

6

fYear

2006

Firstpage

1176

Lastpage

1188

Abstract

Modeling of friction force is cumbersome because of its discontinuity at zero velocity. This paper presents a set of discrete-time friction models for the purpose of haptic rendering and virtual environment construction. These models allow friction to be treated as an admittance-type or impedance-type element of a virtual environment. They are derived from implicit Euler integration of Coulomb-like discontinuous friction and linear mass-spring-damper dynamics, and have closed-form expressions. They include rate-dependent friction laws, and their extension to multidimensional cases is easy in most practical cases. The validity of the models is demonstrated through numerical examples and implementation experiments

Keywords

force feedback; friction; haptic interfaces; telerobotics; Coulomb-like discontinuous friction; admittance representation; admittance-type element; discrete-time friction models; friction force modeling; haptic rendering; impedance representation; impedance-type element; implicit Euler integration; linear mass-spring-damper dynamics; rate-dependent friction laws; virtual environment construction; zero velocity; Admittance; Closed-form solution; Friction; Haptic interfaces; Impedance; Intelligent robots; Kinetic theory; Mechanical engineering; Multidimensional systems; Virtual environment; Admittance; friction; haptic rendering; impedance; implicit Euler scheme;

fLanguage

English

Journal_Title

Robotics, IEEE Transactions on

Publisher

ieee

ISSN

1552-3098

Type

jour

DOI

10.1109/TRO.2006.886262

Filename

4020366